[cig-commits] r15566 - in short/3D/PyLith/branches/pylith-friction/playpen: . friction
surendra at geodynamics.org
surendra at geodynamics.org
Thu Aug 20 12:44:44 PDT 2009
Author: surendra
Date: 2009-08-20 12:44:43 -0700 (Thu, 20 Aug 2009)
New Revision: 15566
Added:
short/3D/PyLith/branches/pylith-friction/playpen/friction/
short/3D/PyLith/branches/pylith-friction/playpen/friction/matprops.spatialdb
short/3D/PyLith/branches/pylith-friction/playpen/friction/twoquad4.cfg
short/3D/PyLith/branches/pylith-friction/playpen/friction/twoquad4.mesh
Log:
Added friction directory with friction test case.
Added: short/3D/PyLith/branches/pylith-friction/playpen/friction/matprops.spatialdb
===================================================================
--- short/3D/PyLith/branches/pylith-friction/playpen/friction/matprops.spatialdb (rev 0)
+++ short/3D/PyLith/branches/pylith-friction/playpen/friction/matprops.spatialdb 2009-08-20 19:44:43 UTC (rev 15566)
@@ -0,0 +1,46 @@
+#SPATIAL.ascii 1
+
+// This database is used to specify the material properties for all of the
+// examples in this directory.
+
+// This follows the format for a Simple DB (the only type presently available).
+SimpleDB {
+
+ // There are 3 values specified in the database, corresponding to density,
+ // S-velocity, and P-velocity (values for shear modulus and Lame's constant
+ // are computed from these values.
+ num-values = 3
+ value-names = density vs vp
+
+ // These are the units used to specify density, vs, and vp.
+ value-units = kg/m**3 m/s m/s
+
+ // Values are only specified at a single point since they are constant
+ // throughout the mesh.
+ num-locs = 1
+
+ // The dimension of the spatial distribution is 0, since it is constant
+ // throughout the mesh.
+ data-dim = 0
+
+ // The spatial dimension of the database is 2.
+ space-dim = 2
+
+ // We are specifying the data in a Cartesian coordinate system.
+ cs-data = cartesian {
+
+ // Our units are already in meters, so we can just multiply by one.
+ to-meters = 1.0
+
+ // We are using a 2D Cartesian coordinate system.
+ space-dim = 2
+ }
+}
+// This is where the data is specified.
+// We only need to specify a single point, since the properties are uniform.
+// The values given here will give a shear modulus and Lame's constant both
+// equal to 30 GPa (Poisson's ratio = 0.25).
+// The entries are:
+// X-coord, Y-coord, density, Vs, Vp.
+
+0.0 0.0 2700.0 3333.333333333333 5773.502691896258
Added: short/3D/PyLith/branches/pylith-friction/playpen/friction/twoquad4.cfg
===================================================================
--- short/3D/PyLith/branches/pylith-friction/playpen/friction/twoquad4.cfg (rev 0)
+++ short/3D/PyLith/branches/pylith-friction/playpen/friction/twoquad4.cfg 2009-08-20 19:44:43 UTC (rev 15566)
@@ -0,0 +1,205 @@
+# -*- Python -*-
+
+# The settings in this file (pylithapp.cfg) will be read automatically
+# by pylith, as long as the file is placed in the run directory.
+
+# The settings in this file will override any settings in:
+# PREFIX/etc/pylithapp.cfg
+# $HOME/.pyre/pylithapp/pylithapp.cfg
+
+# The settings in this file will be overridden by any .cfg file given
+# on the command line or by any command line settings.
+
+[pylithapp]
+
+# ----------------------------------------------------------------------
+# journal
+# ----------------------------------------------------------------------
+# The settings below turn on journal info for the specified components.
+# If you want less output to stdout, you can turn these off.
+[pylithapp.journal.info]
+timedependent = 1
+implicit = 1
+petsc = 1
+solverlinear = 1
+meshioascii = 1
+homogeneous = 1
+elasticityimplicit = 1
+fiatlagrange = 1
+quadrature1d = 1
+faultcohesivedyn = 1
+
+# ----------------------------------------------------------------------
+# mesh_generator
+# ----------------------------------------------------------------------
+# The settings below control the mesh generation (importing mesh info).
+# Turn on debugging output for mesh generation.
+[pylithapp.mesh_generator]
+debug = 0
+
+# This component specification means we are using PyLith ASCII format,
+# and we then specify the filename and number of space dimensions for
+# the mesh.
+[pylithapp.mesh_generator.reader]
+filename = twoquad4.mesh
+coordsys.space_dim = 2
+
+# ----------------------------------------------------------------------
+# problem
+# ----------------------------------------------------------------------
+# Specify the problem settings.
+# This is a time-dependent problem, so we select this as our problem type.
+# We select a total time of 0 sec, and a time step size of 1 sec, so we
+# are performing a single time step.
+# The spatial dimension for this problem is 2.
+# For an implicit formulation (using implicit.cfg), we will perform 1
+# implicit time step from t = -1.0 to t = 0.0 (elastic solution step).
+[pylithapp.timedependent]
+dimension = 2
+normalizer.length_scale = 1.0*m
+formulation = pylith.problems.Implicit
+
+# Set bc to an array with 2 boundary conditions: 'x_neg' and 'x_pos'.
+bc = [x_neg,x_pos]
+
+# Set interfaces to an array with 1 fault: 'fault'.
+interfaces = [fault]
+
+
+[pylithapp.timedependent.formulation.time_step]
+total_time = 0.0*s
+dt = 1.0*s
+
+
+# ----------------------------------------------------------------------
+# materials
+# ----------------------------------------------------------------------
+# Specify the material information for the problem.
+# The material type is isotropic elastic formulated for plane strain.
+[pylithapp.timedependent.materials]
+material = pylith.materials.ElasticPlaneStrain
+
+[pylithapp.timedependent.materials.material]
+
+# We give a label of 'elastic material' to this material.
+label = elastic material
+
+# The cells associated with this material are given a material ID of 0
+# in the mesh file.
+id = 0
+
+# The properties for this material are given in the spatial database file
+# 'matprops.spatialdb'.
+db_properties.iohandler.filename = matprops.spatialdb
+
+# Set cell type to quadrilateral (2-d Lagrange).
+quadrature.cell = pylith.feassemble.FIATLagrange
+quadrature.cell.dimension = 2
+
+# ----------------------------------------------------------------------
+# boundary conditions
+# ----------------------------------------------------------------------
+# Provide information on the boundary conditions.
+
+# Boundary conditions to be applied to the negative x-side of the mesh.
+[pylithapp.timedependent.bc.x_neg]
+
+# We are fixing the 0 (x) and 1 (y) degrees of freedom.
+bc_dof = [0, 1]
+
+# The nodes associated with this boundary condition have the name
+# 'x_neg' in the mesh file.
+label = x_neg
+
+db_initial = spatialdata.spatialdb.UniformDB
+db_initial.label = Dirichlet BC -x edge
+db_initial.values = [displacement-x,displacement-y]
+db_initial.data = [0.1*m,0.0*m]
+
+# Boundary conditions to be applied to the positive x-side of the mesh.
+[pylithapp.timedependent.bc.x_pos]
+
+# We are fixing the 0 (x) and 1 (y) degrees of freedom.
+bc_dof = [0, 1]
+
+# The nodes associated with this boundary condition have the name
+# 'x_pos' in the mesh file.
+label = x_pos
+
+db_initial = spatialdata.spatialdb.UniformDB
+db_initial.label = Dirichlet BC +x edge
+db_initial.values = [displacement-x,displacement-y]
+db_initial.data = [-0.1*m,0.0*m]
+
+# ----------------------------------------------------------------------
+# faults
+# ----------------------------------------------------------------------
+# Provide information on the fault (interface).
+[pylithapp.timedependent.interfaces]
+
+fault = pylith.faults.FaultCohesiveDyn
+
+# Define fault properties.
+[pylithapp.timedependent.interfaces.fault]
+
+# The nodes associated with this fault have the name 'fault' in the mesh file.
+label = fault
+
+# NOTE: It is possible to assign an ID number to a fault (e.g.,
+# 'id = 10'). Care must be taken when doing this, however, because the
+# assigned ID will become the material ID for the cohesive element.
+# This ID must not conflict with any of the material ID numbers for
+# volume elements. The default ID for a fault is 100. If you have a
+# fault in your mesh you must:
+# 1. If you create your own fault ID, make sure it does not conflict
+# with any of you material ID's.
+# 2. If you use the default fault ID, make sure that none of your
+# material ID's are equal to 100.
+
+# The quadrature for a 2D fault is 1D with a linear shape.
+quadrature.cell = pylith.feassemble.FIATLagrange
+quadrature.cell.dimension = 1
+
+db_initial_tractions = spatialdata.spatialdb.UniformDB
+db_initial_tractions.label = "Initial fault tractions"
+db_initial_tractions.values = [traction-shear,traction-normal]
+db_initial_tractions.data = [0.0*Pa, -10.0*MPa]
+
+# ----------------------------------------------------------------------
+# PETSc
+# ----------------------------------------------------------------------
+# We are using all of the default settings for PETSc except for
+# specifying the block Jacobi preconditioner. Additional PETSc
+# command-line arguments may be found in the PETSc documentation.
+[pylithapp.petsc]
+ksp_rtol = 1.0e-8
+pc_type = asm
+# Change the preconditioner settings (must turn off
+# shift_positive_definite and turn on shift_nonzero).
+sub_pc_factor_shift_positive_definite = 0
+sub_pc_factor_shift_nonzero =
+
+ksp_monitor = true
+ksp_view = true
+log_summary = true
+ksp_max_it = 100
+ksp_gmres_restart = 50
+#start_in_debugger = true
+
+# ----------------------------------------------------------------------
+# output
+# ----------------------------------------------------------------------
+# Give basename for VTK domain output of solution over domain.
+[pylithapp.problem.formulation.output.output.writer]
+filename = twoquad4.vtk
+
+# Give basename for VTK fault output.
+[pylithapp.timedependent.interfaces.fault.output]
+writer.filename = twoquad4-fault.vtk
+cell_info_fields = []
+cell_data_fields = []
+
+# Give basename for VTK output of state variables.
+[pylithapp.timedependent.materials.material.output]
+cell_filter = pylith.meshio.CellFilterAvgMesh
+writer.filename = twoquad4-statevars.vtk
Added: short/3D/PyLith/branches/pylith-friction/playpen/friction/twoquad4.mesh
===================================================================
--- short/3D/PyLith/branches/pylith-friction/playpen/friction/twoquad4.mesh (rev 0)
+++ short/3D/PyLith/branches/pylith-friction/playpen/friction/twoquad4.mesh 2009-08-20 19:44:43 UTC (rev 15566)
@@ -0,0 +1,133 @@
+// Finite-element mesh with two quad4 cells.
+//
+//
+// 1 ----- 3 ----- 5
+// | | |
+// | | |
+// | | |
+// 0 ----- 2 ----- 4
+//
+// Each edge has a length of 2.0.
+//
+mesh = {
+
+ // Dimenion associated with topology of mesh.
+ dimension = 2
+
+ // We are using zero-based indexing (default, C style) rather than
+ // one-based (Fortran style) indexing.
+ use-index-zero = true
+
+ // Vertices in the mesh.
+ vertices = {
+
+ // Dimension of coordinate system for vertices.
+ dimension = 2
+
+ // Number of vertices in mesh.
+ count = 6
+
+ // Coordinates are listed as:
+ // Vertex number (starting from zero), x-coord, y-coord
+ // Use coordinate units that are consistent with the other units used.
+ coordinates = {
+ 0 -2.0 -1.0
+ 1 -2.0 1.0
+ 2 0.0 -1.0
+ 3 0.0 1.0
+ 4 2.0 -1.0
+ 5 2.0 1.0
+ }
+ }
+
+ // Finite-element cells in the mesh.
+ cells = {
+
+ // There are 2 cells.
+ count = 2
+
+ // These are bilinear quadrilateral cells, so there are 4 corners per cell.
+ num-corners = 4
+
+ // List the vertices composing each cell, moving counter-clockwise
+ // around the cell.
+ // List the information as:
+ // Cell number (starting from zero), vertex 0, vertex 1, vertex 2, vertex 3
+ simplices = {
+ 0 0 2 3 1
+ 1 4 5 3 2
+ }
+
+ // List the material ID's associated with each cell.
+ // Different ID's may be used to specify a different material type, or
+ // to use a different spatial database for each material ID.
+ // In this example, cells 0 and 1 both are associated with material ID 0.
+ material-ids = {
+ 0 0
+ 1 0
+ }
+ }
+
+ // Here we list different groups (cells or vertices) that we want to
+ // associate with a particular name.
+
+ // This group of vertices may be used to define a fault.
+ // There are 2 vertices corresponding to indices 2 and 3.
+ group = {
+ name = fault
+ type = vertices
+ count = 2
+ indices = {
+ 2
+ 3
+ }
+ }
+
+ // This group of vertices may be used to specify boundary conditions.
+ // There are 3 vertices corresponding to indices 0, 2, and 4.
+ group = {
+ name = y_neg
+ type = vertices
+ count = 3
+ indices = {
+ 0
+ 2
+ 4
+ }
+ }
+
+ // This group of vertices may be used to specify boundary conditions.
+ // There are 2 vertices corresponding to indices 0 and 1.
+ group = {
+ name = x_neg
+ type = vertices
+ count = 2
+ indices = {
+ 0
+ 1
+ }
+ }
+
+ // This group of vertices may be used to specify boundary conditions.
+ // There are 2 vertices corresponding to indices 4 and 5.
+ group = {
+ name = x_pos
+ type = vertices
+ count = 2
+ indices = {
+ 4
+ 5
+ }
+ }
+
+ // This group of vertices may be used to specify boundary conditions.
+ // There is 1 vertex corresponding to index 3.
+ group = {
+ name = y_pos
+ type = vertices
+ count = 1
+ indices = {
+ 3
+ }
+ }
+}
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